Inductive power transfer
地域:
CT
CT Shelton
摘要
One embodiment provides a non-contact power transmitter device including a sealed housing provided at least partially within a surface, and a transmitter coil within the sealed housing configured to inductively transfer power to a power receiver device. The power transmitter device also includes a transmitter control unit coupled to the transmitter coil, a transceiver configured to communicate with the power receiver device, and an electronic processor coupled to the transmitter control unit and the transceiver. The electronic processor is configured to establish, using the transceiver, communication with the power receiver device, and negotiate power transfer requirements between the power transmitter device and the power receiver device. The electronic processor is also configured to control the transmitter coil unit to transfer power to the power receiver device.
說明書
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This application claims priority to U.S. Provisional Patent Application No. 62/815,128, filed Mar. 7, 2019, the entire contents of which are hereby incorporated by reference.
The present disclosure relates generally to inductive power transfer between electrical devices.
Users of electrical devices often prefer such devices without wires to prevent tripping and damage to electrical devices due to inadvertent pulling of power cords during operation or when the electrical devices are moved. Additionally, elimination of wires also simplifies the design of electrical devices. Electrical devices without wires are typically powered by batteries. Batteries, however, have limited run-time and capacity. Mid-power range devices such as office and home appliances consume between approximately 0.1 to 3.2 kilowatts of power. To power these devices using batteries requires very large batteries affecting the portability of the devices. Additionally, batteries must typically be charged regularly, which requires wired chargers and decommissioning of the device while the batteries are being charged.
Additionally, in harsh or hazardous environments, sealed/waterproof electrical devices are needed. In these environments, power cords and exposed power outlets may pose an additional hazard to the environment.
Accordingly, there is a need for wireless mid-range power transfer systems that improve the portability and user accessibility of electrical devices. Additionally, there is a need for wireless mid-range power transfer systems that are sealed and are waterproof.
權(quán)利要求
We claim:1. A non-contact power transmitter device comprising:a sealed housing; a transmitter coil within the sealed housing configured to inductively transfer power to a power receiver device; a transmitter control unit coupled to the transmitter coil; a transceiver configured to communicate with the power receiver device; an electronic processor coupled to the transmitter control unit and the transceiver and configured toestablish, using the transceiver, an out-of-band communication with the power receiver device, negotiate power transfer requirements between the power transmitter device and the power receiver device using the out-of-band communication, and control the transmitter control unit to transfer power to the power receiver device; and a flat base portion, wherein the transmitter coil is provided in the flat base portion, and wherein the flat base portion is configured to be aligned with a flat portion of the power receiver device, wherein the receiver coil of the power receiver device is provided in the flat portion, and wherein the flat base portion and the flat portion are aligned to axially align the transmitter coil and the receiver coil without an air gap between the flat base portion and the flat portion. 2. The non-contact power transmitter device of claim 1 , wherein the transmitter control unit is configured toprovide a first alternating current to the transmitter coil; and generate, using the transmitter coil, an oscillating magnetic field, wherein the oscillating magnetic field generates a second alternating current in a receiver coil of the power receiver device. 3. The non-contact power transmitter device of claim 1 , wherein the sealed housing is provided at least partially within the ground. 4. The non-contact power transmitter device of claim 1 , further comprising:a first magnet provided in the flat base portion, the first magnet provided in a center of the transmitter coil; and a second magnet provided in the flat portion, the second magnet provided in a center of the receiver coil, wherein when the flat portion is aligned with the flat base portion, the first magnet is coupled to the second magnet due to the magnetic force between the first magnet and the second magnet. 5. The non-contact power transmitter device of claim 1 , further comprising:a second transmitter coil within the sealed housing configured to inductively transfer power to a second power receiver device; wherein the electronic processor is further configured to:establish, using the transceiver, communication with the power receiver device and the second power receiver device, determine priority and power requirements of the power receiver device and the second power receiver device based on the communication with the power receiver device and the second power receiver device, and control the transmitter coil unit to divide power between the transmitter coil and the second transmitter coil based on the priority and power requirements. 6. A building comprising:a surface including the non-contact power transmitter of claim 1 , wherein the sealed housing is provided at least partially within the surface. 7. The building of claim 6 , herein the surface is one selected from a group consisting of a vertical surface and a horizontal surface. 8. A non-contact power transmitter device comprising:a sealed housing; a transmitter coil within the sealed housing configured to inductively transfer power to a power receiver device; a transmitter control unit coupled to the transmitter coil; a transceiver configured to communicate with the power receiver device; an electronic processor coupled to the transmitter control unit and the transceiver and configured toestablish, using the transceiver, an out-of-band communication with the power receiver device, negotiate power transfer requirements between the power transmitter device and the power receiver device using the out-of-band communication, and control the transmitter control unit to transfer power to the power receiver device; a flat base portion, wherein the transmitter coil is provided in the flat base portion; and a raised ledge portion around the flat base portion having an opening on an inner side of the raised ledge portion, wherein the raised ledge portion and the flat base portion are configured to receive a raised portion of the power receiver device, and wherein a receiver coil of the power receiver device is provided in the raised portion. 9. The non-contact power transmitter device of claim 8 , further comprising:a first magnet provided in the flat base portion, the first magnet provided in a center of the transmitter coil; and a second magnet provided in the raised portion, the second magnet provided in a center of the receiver coil, wherein when the raised portion is received in the opening formed by the raised ledge portion, the first magnet is coupled to the second magnet due to the magnetic force between the first magnet and the second magnet. 10. A non-contact power transfer system comprising:a power transmitter device includinga sealed housing provided at least partially within a surface, a transmitter coil within the sealed housing, a transmitter control unit coupled to the transmitter coil, a transmitter transceiver, and a transmitter electronic processor coupled to the transmitter control unit and the transceiver; and an electrical appliance including a power receiver device configured to be coupled in a power transfer relationship with the power transmitter device, the power receiver device includinga second sealed housing provided at least partially within the electrical appliance, a receiver coil within the sealed housing, wherein the transmitter coil is configured to inductively transfer power to the receiver coil, a power conversion unit coupled to the receiver coil, a receiver transceiver, and a receiver electronic processor coupled to the power conversion unit and the receiver transceiver, wherein the transmitter electronic processor is configured toestablish, using the transmitter transceiver, an out-of-band communication with the power receiver device, negotiate power transfer requirements between the power transmitter device and the power receiver device using the out-of-band communication, and control the transmitter control unit to transfer power to the power receiver device; wherein the power receiver device further comprises a raised portion, wherein the receiver coil of the power receiver device is provided in the raised portion, and wherein the power transmitter device further comprises: a flat base portion, wherein the transmitter coil is provided in the flat base portion; and a raised ledge portion around the flat base portion having an opening on an inner side of the raised ledge portion, wherein the raised ledge portion and the flat base portion are configured to receive the raised portion of the power receiver device. 11. The non-contact power transfer system of claim 10 , wherein the transmitter coil unit is configured toprovide a first alternating current to the transmitter coil, and generate, using the transmitter coil, an oscillating magnetic field, wherein the oscillating magnetic field generates a second alternating current in the receiver coil. 12. The non-contact power transfer system of claim 11 , wherein the power conversion unit is configured toconvert the second alternating current to a direct current; and provide the direct current to a load of the power receiver device. 13. The non-contact power transfer system of claim 11 , wherein the power conversion unit is configured toconvert the second alternating current to output power; and provide the output power to a load of the power receiver device. 14. The non-contact power transfer system of claim 13 , wherein the second alternating current is a single phase alternating current and wherein converting the second alternating current to the output power includes converting the single-phase alternating current to three-phase alternating current. 15. The non-contact power transfer system of claim 10 , wherein the sealed housing is provided at least partially within the ground. 16. The non-contact power transfer system of claim 10 , wherein the power transmitter device further comprises a flat base portion, wherein the transmitter coil is provided in the flat base portion, andwherein the power receiver device further comprises a flat portion configured to be aligned with the flat base portion of the power transmitter device, wherein the receiver coil is provided in the flat portion, wherein the flat base portion and the flat portion are aligned to axially align the transmitter coil and the receiver coil without an air gap between the flat base portion and the flat portion. 17. A building comprising:a surface including at least a portion of the non-contact power transfer system of claim 10 , wherein the sealed housing is provided at least partially within the surface. 18. The building of claim 17 , wherein the surface is one selected from a group consisting of a vertical surface and a horizontal surface.
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